Influence of muscle forces on femoral strain distribution
Influence of muscle forces on femoral strain distribution
Musculoskeletal loading influences the stresses and strains within the human femur and thereby affects the processes of bone modeling and remodeling. It is essential for implant design and simulations of bone modeling processes to identify locally high or low strain values which may lead to bone resorption and thereby affect the clinical outcome. Using a finite element model the stresses and strains of a femur with all thigh muscle and joint contact forces were calculated for four phases of a gait cycle. Reduced load sets with only a few major muscles were analyzed alternatively. In a completely balanced femur with all thigh muscles the stress and strain patterns are characterized by combined bending and torsion throughout the bone. Similar to in vivo recordings, the model with all thigh muscles showed peak surface strains below 2000 mu epsilon (45% gait cycle). Under simplified load regimes surface strains reached values close to 3000 mu epsilon. Within the proximal femur, the simplified load regimes produced differences in strain as high as 26% in comparison to those with all thigh muscles included. This difference is reduced to 5% if the adductors are added to a loading consisting of hip contact, abductors and ilio-tibial band. This study demonstrates the importance of an ensemble of muscle forces to reproduce a physiological strain distribution in the femur. Analytical attempts to simulate bone modeling, remodeling or bone density distributions should therefore rely on fully balanced external load regimes which account for the role of the various soft tissue forces.
biomechanics, bone remodeling, bone physiology, femur physiology, finite element analysis, gait, human, models, biological, muscle, skeletal physiology, skeletal stress, mechanical
841-846
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Heller, M.
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Albinger, J.
8d962618-bfa4-4773-96ac-7f607b4f3a1a
Schulz, O.
8090c23b-64a4-4bcc-bfa2-f4826809edc3
Schneider, E.
b167e316-fd44-42d5-8ef0-d49e411aebef
Claes, L.
0d49608f-bb00-4db4-8ad1-458bf9f59550
1 September 1998
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Heller, M.
3da19d2a-f34d-4ff1-8a34-9b5a7e695829
Albinger, J.
8d962618-bfa4-4773-96ac-7f607b4f3a1a
Schulz, O.
8090c23b-64a4-4bcc-bfa2-f4826809edc3
Schneider, E.
b167e316-fd44-42d5-8ef0-d49e411aebef
Claes, L.
0d49608f-bb00-4db4-8ad1-458bf9f59550
Duda, G.N., Heller, M., Albinger, J., Schulz, O., Schneider, E. and Claes, L.
(1998)
Influence of muscle forces on femoral strain distribution.
Journal of Biomechanics, 31 (9), .
(PMID:9802785)
Abstract
Musculoskeletal loading influences the stresses and strains within the human femur and thereby affects the processes of bone modeling and remodeling. It is essential for implant design and simulations of bone modeling processes to identify locally high or low strain values which may lead to bone resorption and thereby affect the clinical outcome. Using a finite element model the stresses and strains of a femur with all thigh muscle and joint contact forces were calculated for four phases of a gait cycle. Reduced load sets with only a few major muscles were analyzed alternatively. In a completely balanced femur with all thigh muscles the stress and strain patterns are characterized by combined bending and torsion throughout the bone. Similar to in vivo recordings, the model with all thigh muscles showed peak surface strains below 2000 mu epsilon (45% gait cycle). Under simplified load regimes surface strains reached values close to 3000 mu epsilon. Within the proximal femur, the simplified load regimes produced differences in strain as high as 26% in comparison to those with all thigh muscles included. This difference is reduced to 5% if the adductors are added to a loading consisting of hip contact, abductors and ilio-tibial band. This study demonstrates the importance of an ensemble of muscle forces to reproduce a physiological strain distribution in the femur. Analytical attempts to simulate bone modeling, remodeling or bone density distributions should therefore rely on fully balanced external load regimes which account for the role of the various soft tissue forces.
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Published date: 1 September 1998
Keywords:
biomechanics, bone remodeling, bone physiology, femur physiology, finite element analysis, gait, human, models, biological, muscle, skeletal physiology, skeletal stress, mechanical
Organisations:
Bioengineering Group
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Local EPrints ID: 348484
URI: http://eprints.soton.ac.uk/id/eprint/348484
ISSN: 0021-9290
PURE UUID: fc5c4a69-db85-4025-b232-9c222cc36145
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Date deposited: 26 Feb 2013 10:15
Last modified: 23 Jul 2022 02:05
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Author:
G.N. Duda
Author:
J. Albinger
Author:
O. Schulz
Author:
E. Schneider
Author:
L. Claes
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